Development and Characterization of Adsorbent from Rice Husk Ash to Bleach Vegetable Oils
1. IOSR Journal of Applied Chemistry (IOSR-JAC)
e-ISSN: 2278-5736.Volume 4, Issue 2 (Mar. – Apr. 2013), PP 42-49
www.iosrjournals.org
www.iosrjournals.org 42 | Page
Development and Characterization of Adsorbent from Rice Husk
Ash to Bleach Vegetable Oils.
1
Otaru, A.J., 2
Ameh, C.U., A.S., 3
Abdulkareem, A.S., 4
Odigure, J.O. and
5
Okafor, J.O.
1,3,4&5
(Department of Chemical Engineering, Federal Univeristy of Technology, PMB 065, Gidan Kwanu,
Minna, Niger State, Nigeria).
2
(Chevron Nigeria Limited, 2, Chevron Drive, Lekki, Lagos, Nigeria)
(Published in honour of Jacqueline C. Schindler)
Abstract: The study is aimed at characterization and development of adsorbent from rice husk ash to
bleach vegetable oil. The vegetable oil bleached was groundnut oil, palm kernel oil and palm oils. Rice
husk sample were pre-treated with different concentration of HCl. The characterization of the rice husk
ash was tested by varying the temperature and time interval before it was subsequently calcined at 600 ℃
for three hours (i.e. having a constant temperature and time interval for calcinations). The optimum
temperature and burning time was observed to be 600 ℃ for 3 hrs. A yield of 2.5M HCl was recorded as
the best bleaching potential of palm kernel and palm oil and 2M HCl for groundnut oil. The result
obtained showed that acid treatment improve the bleaching potential of the rice husk ash. Graphical
interpretation of results obtained indicates that the unbleached oil is directly proportional to the
wavelength.
Keywords: Characterization, Development, Adsorbent, Rice husk and Vegetable oil.
I. Introduction
Rice (Oryza Sativa) is grown over vast area of land around the world and is a major staple food for more
than a half of the world population (Juliano, 1985). The Asian continent accounts for approximately 90 percent
of rice production and is also the major customer. However, Rice is cultivated in virtually all the agro-ecological
zones in Nigeria. Significant improvement in rice production in Nigeria occurred in 1980 when output increased
to about a million tons while area cultivated and yield rose to 550 thousand hectares and 1.98tonnes per hectares
respectively (Tunji, et al., 2007). About 108
tons of rice husk is generated annually in the world. In Nigeria,
about 2million tones of rice is produced annually, while in Niger State, about 96000 tons of rice grains is
produced in 2000 (Alhassan, 2005).
Global production of rice, the majority of which is grown in Asian, is approximately 550million
tons/year. The milling of rice generates a waste material, while husk is the material surrounding the rice grain.
The annual Worldwide output of rice husk is approximately 80million tons, which corresponds to 3.2 million
tons of silica /year globally (Natarajan, et al., 1998).
Rice husk are rich in cellulose (28-36 %), crude fibre (34.5-45.9 %) and ash (13.2-21.0 %) (Juliano,
1985). The environmentally sound disposal and use of large quantities of hull is a challenging issue for rice
processors around the world. The rice hull energy content at 14.0 % moisture content is 11.9 – 13.0MJ/Kg
(5,116.5-5,589.4 Btu/Ib) (Velupillai et al., 1997). In developing countries, like India, where rice milling
industries are small and scattered, hulls are used as a part of brick kilns, as an ingredient in dung-cake, as
components in goldsmith or blacksmith furnaces or as a fuel for water heating systems (GovindRao, 1980).
Managing rice husk is a problem especially in developing countries like Nigeria, where there is no any proper
method of waste disposal in place. There is therefore the need to seek for way of converting the waste into hotter
resources. Development of adsorbent from the rice husk is considered a perfect means of controlling the
problems of rice husk as a waste.
Rice husk ash (RHA) is an end product of the combustion of rice husk. Rice husk ash has good adsorbent
properties because of its high silica content (Velupillai et al., 1997). Rice husk ash has been successfully applied
as adsorbent for several lipid components such as phospholipids (Brown and Snyder, 1989), lute in (Proctor and
Palaniappan, 1990), palmitic and oleic acids (Ooi and Leong, 1991), carotene (Liew et al., 1993) and saturated
fatty acids. The type of ash varies considerably depends on the techniques employed for calcinations. The silica
in the ash undergoes structural transformation depending on the temperature during combustion. At 600 ℃
amorphous silica is formed, whereas 700 ℃ is a transition region from amorphous to crystalline silica while at
800 ℃ and above till the melting point of the ash, only crystalline silica is formed.
2. Development And Characterization Of Adsorbent From Rice Husk Ash To Bleach Vegetable Oils.
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This study is focus on the development of adsorbent from rice husk for the bleaching of vegetable oil
using various pretreated and untreated samples.
II. Research Methodology
Preparation of the Rice Husk
The rice husk was washed thoroughly with de- ionized water to remove dirt and then dried in an oven for
three and the half hours at 130 ℃.
Pre-treatment
60 g of the clean and dried rice husks each was treated with different concentration of HCl in the range of
0.5-2.5M at 0.5M interval. Acid leaching was performed by boiling at 90 ℃ for 3 hours with acid/rice husk ratio
10 ml: 1g. After leaching, the Pre-treated rice husk were washed in plenty of distilled water and tested with pH
meter for neutrality and then dried in the oven at 110℃ for three and the half hours. The colors of the pre-treated
rice husk were observed.
Calcination process
The pre-treated samples plus untreated samples of the rice husks were charred in the oven at 110℃ for
four hours. The ash was prepared by burning the rice husks inside a muffle furnace at 600 ℃ for 3 hours which
was obtained by variation of temperature from 500-800 ℃ at an interval of 100 ℃ and time of the ash (1, 2 and
3 hours), in a porcelain crucible placed in an electric furnace and then cooled at room temperature. The selected
temperature and time (600 ℃ for 3 hour) gave the best characterization results in terms of ash content, fixed
carbon, and moisture content and from literature since we are interested in amorphous silica and not crystalline
silica in terms of ash content.
Bleaching of Vegetable Oils
0.5 g of the powdered ash from each sample was used to bleach 20 ml each of groundnut oil, palm oils
and palm kernel oil. Bleaching was carried out at a constant temperature and time at 80 ℃ for 30 minutes
respectively with constant stirring using magnetic stirrer on a magnetic hotplate. It was also followed by
filtering the slurry using a vacuum pump. The filtered oil samples were then analyzed using a spectrophotometer
at different wavelengths at the visible region between 380 nm-800 nm.
Characterization of Rice Husk Ash, Bulk Density Determination
A measuring cylinder (ml) was used to measure a certain amount of water. Another measuring cylinder
is then used to measure the rice husk ash which is then poured into the water in the first measuring cylinder, the
volume of the water increases. The volume in the water formerly in the cylinder (𝑉1) then subtracted from the
new volume of the water (𝑉2) and the change in the volume is then divided by known weight of the rice husk
ash, then the bulk density is obtained. (Oyetola and Abdullahi, 2006)
Characterization of the Developed Adsorbent
The following test was carried out in order to fully specify the characterization of activated carbon for the
rice husk.
Determination of Ash Content
This was carried out in accordance to standard ASTM D 2866 (1987) method. 20 g of the dry pre-treated
sample was placed in a porcelain crucible, weigh of crucible plus weight of dry rice husk was noted and
recorded as 𝑊2. The sample was then transferred into a muffle furnace (Apex, 1999) set at a temperature of
600 ℃ for 3 hours after which it was removed and allowed to cool at room temperature. The crucible and its
content were reweighed and the weight was recorded as 𝑊3. This process was carried out for all samples. The
ash content was calculated using the formula;
Ash content=
𝑊 𝑎𝑠ℎ
𝑊 𝑅𝐻
× 100 =
𝑊2−𝑊3
𝑊0
× 100
Where 𝑊𝑎𝑠ℎ = weight of ash after heating = 𝑊2-𝑊3, 𝑊0= Original weight of sample.
Moisture Content Determination
This procedure is in accordance with standard ASTM (1987) method. 20 g of sample were weighed into a
paddy dish and the weight of the sample plus paddy dish was noted as 𝑊2. The sample is then placed in a
porcelain crucible and charred into the muffle furnace at a temperature of about 600 ℃ for 3 hours. It was then
cooled at room temperature and it was then placed back into a paddy dish and reweighed.
3. Development And Characterization Of Adsorbent From Rice Husk Ash To Bleach Vegetable Oils.
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Moisture content (MC) =
𝑊2− 𝑊3
𝑊2 − 𝑊1
× 100
Where 𝑊2 = Original weight of sample + Crucible.
𝑊1 = Weight of Crucible.
𝑊3 = Dried weight of sample + Crucible.
Yield of charcoal
This was obtained by calculation (Ekanem, 1996)
Yield (Ych) =
𝑤𝑡 𝑜𝑓 𝑆+𝐶 𝑏− 𝑤𝑡 𝑜𝑓 𝑆+𝐶 𝑎
𝑤𝑡 𝑜𝑓 𝑆+𝐶 𝑏
×100
Where (wt of S+C)b = Weight of sample +Crucible before ashing.
(Wt of S+C)a = Weight of sample + Crucible after ashing.
Fixed carbon determination
This was conducted according to the procedure in ASTM (1987). The fixed carbon content was
determined by;
Fixed carbon content=
𝑌𝑐ℎ−𝐴𝑐−𝑀𝑐
𝑌𝑐ℎ
×100
Pore volume determination
The pore volume was determined according to smith (1981). 20 g of the sample was weighed into a paddy
dish and the weight of the sample plus paddy dish was noted and recorded as 𝑊0. During pre-treatment some
amount of acid was poured into the sample and it was boiled for about 3hours for a temperature of 90 ℃. After
the air in the pore had been displaced, the weight was recorded as W. This procedure was carried out for all
samples.
Pore volume (𝑐𝑚3
/g) = (𝑊𝐷𝑠 /𝜌 𝑤 ) or (
𝑊0− 𝑊1
𝑊− 𝑊1
)/ density of water.
Where 𝑊1=weight of paddy dish, 𝑊0= initial weight of sample and paddy dish, W= final weight of sample and
paddy dish, 𝜌 𝑤 =density of water 1 g/𝑐𝑚3
, 𝑊𝐷𝑠 =weight of dry sample.
Determination of Porosity and Void Volume
The porosity is determined according to smith (1981) by calculation.
Porosity (𝑃0) = 𝑉𝑣/𝑉𝑡
Where 𝑉𝑡 = Total volume and 𝑉𝑣 is the void volume.
The void volume was obtained first by determining the total volume of the cylinder (𝑉𝑡 =𝜋𝑟2
h) used for the
experiment and also the volume of the solid is determined i.e. the activated carbon/ash used.
𝑉𝑆=
𝑀𝑆
𝐺𝑆
𝜌 𝑤
Where r = radius
h= height
𝑀𝑠= Mass of solid
𝐺𝑠= Specific gravity
𝜌 𝑤 = Density of water
Then Void Volume (𝑉𝑣) was obtained as
𝑉𝑣 = 𝑉𝑡 - 𝑉𝑠
III. Results And Discussions
The results of the characterization and development of adsorbent from rice husk ash to bleach vegetable
oil are presented in tabular and graphical forms.
Characterization of rice husk carbonized ash
Characterization of rice husk carbonized ash is characterized at different temperature ranging from 500-
800 ℃ and at different time interval. The results obtained on various analysis conducted in this study are
presented below.
4. Development And Characterization Of Adsorbent From Rice Husk Ash To Bleach Vegetable Oils.
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Table 1: Characterization of Rice Husk Carbonized Ash at Different Temperature
(Constant Time=1hour and mass of sample=20 g)
Temperature
℃
Ash content
(g)
Porosity Moisture
content (%)
Fixed carbon
(%)
Charcoal yield
(%)
500 6.78 0.938 7.16 86.50 66.10
600 5.88 0.939 7.10 87.82 70.60
700 5.72 0.940 7.08 87.94 71.40
Table 2: Characterization of Rice Husk Carbonized Ash at Different Temperature
(Constant Time=2 hours)
Temperature
℃
Ash content
(g)
Porosity Moisture
content (%)
Fixed carbon
(%)
Charcoal yield
(%)
500 5.451 0.942 7.08 82.81 72.75
600 5.740 0.942 7.03 82.09 71.30
700 5.540 0.945 6.99 82.67 72.30
Table 3: Characterization of Rice Husk Carbonized Ash at Different Temperature
(Constant Time=3 hours)
Temperature
℃
Ash content
(g)
Porosity Moisture
content (%)
Fixed carbon
(%)
Charcoal yield
(%)
500 5.420 0.949 7.28 82.58 72.90
600 5.999 0.951 6.63 81.95 70.01
700 5.131 0.950 6.63 84.17 74.35
Table 4: Characterization of Rice Husk Carbonized Ash at Different Time Interval
(Constant Temperature=600 ℃)
Time
Hours
Ash content
(g)
Porosity Moisture
content (%)
Fixed carbon
(%)
Charcoal
yield (%)
1 5.880 0.939 7.10 87.82 70.60
2 5.740 0.942 7.03 82.09 71.30
3 5.999 0.951 6.63 81.95 70.01
Table 5: Characterization of the Developed Adsorbent using HCl as Activating Agent
Properties 0.5M 1M 1.5M 2M 2.5M
Ash Content (g) 10.03 10.47 10.86 10.85 10.83
Moisture
Content (%)
3.01 3.11 3.24 3.24 3.14
Yield of
Charcoal (%) 75.95 76.1 76.57 76.61 75.83
Fixed Carbon
(%)
82.83 82.16 81.59 81.61 81.58
Porosity 0.935 0.935 0.937 0.936 0.937
Bulk Density
(g/cm3
)
0.37 0.36 0.34 0.30 0.34
5. Development And Characterization Of Adsorbent From Rice Husk Ash To Bleach Vegetable Oils.
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Figure 1: The Effect of Varying Concentration of HCl Acid Pre-treated RHA for Bleaching of Groundnut Oil.
Figure 2: The Effect of Varying Concentration of HCl Acid Pre-treated RHA for Bleaching of Palm Kernel Oil.
0
0.05
0.1
0.15
0.2
0.25
0.3
0.35
0.4
0.45
480 520 560 600 640 680 720 760 800
Unbleached
oil
Untreated
RHA
0.5M HCl
1M HCl
1.5M HCl
2M HCl
ABSORBANCE
WAVELENGTH
0
0.2
0.4
0.6
0.8
1
1.2
1.4
1.6
1.8
2
480 520 560 600 640 680 720 760 800
Unbleached oil
Untreated RHA
0.5M HCl
1M HCl
1.5M HCl
2M HCl
2.5M HCl
WAVELENGTH(nm)
6. Development And Characterization Of Adsorbent From Rice Husk Ash To Bleach Vegetable Oils.
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Figure 3: The Effect of Varying Concentration of HCl Acid Pre-treated RHA for Bleaching of Palm Oil.
IV. Discussion Of Results
The physical appearance of untreated rice husk was seen to be brownish before pre-treatment. After pre-
treatment, it was seen to be light yellowish in colour due to the concentration of acid added to the husk. The
light yellowish colour indicates that the pre-treatment of the rice husk has increased the surface area of the rice
husk after treatment.
Table 1 represents the effect of carbonization temperatures at constant carbonization time of 1 hour on
the analytics of carbonized rice husk. It can be observed from table 1 that as carbonization increases from 500-
700℃, the ash content of the rice husk decreased from 6.78-5.72. The reduction in ash content with increase in
temperature can be attributed to the effect of an increase in the temperature of the muffle furnace. The shrinkage
of the ash present in the furnace increases the dielectric loss factor due to an increase in temperature of the rice
husk burned inside the furnace. Also presented in table 1, is the effect of temperature on the porosity of the
carbonized rice husk. The result shows that an increase in temperature resulted into increase in porosity of the
carbonized rice husk.
Table 2 represents the effect of carbonization temperatures at constant carbonization time of 2 hours on
the analytics of carbonizing rice husk ash. It can be observed from this table that as carbonization increases in
temperature from 500-600 ℃, the ash content of the rice husk increases from 5.451-5.740. The increase in ash
content with an increase in temperature can be attributed to the effect of shrinkage of the burning husk due to
reactivity and its pozzolanic properties. Also the carbon content present in the ash also decreases with an
increase in the ash content. In other words some carbon present in the ash turn into ash in order to increase the
silica content present in the ash. At 600-700 ℃, the ash content of the rice husk decreases from 5.74-5.54. The
reduction in the ash content with an increase in temperature can be attributed to the effect of shrinkage of the
ash present in the muffle furnace and also the silica content is transferred from amorphous stage to crystalline
stage. It also increases the dielectric loss factor due to an increase in temperature of the rice husk. Also
presented in table 2, is the effect on the porosity of the carbonized rice husk. An increase in temperature leads to
an increase in the porosity of the carbonized rice husk at a constant time interval.
Table 3 represents the effect of carbonization temperatures at constant carbonization time of 3 hours on
the analytics of carbonizing rice husk ash. It can be observed from this table that as carbonization increases in
temperature from 500-600 ℃, the ash content of the rice husk increases from 5.420-5.999. The increase in ash
content with an increase in temperature can be attributed to the effect of shrinkage of the burning husk due to
reactivity and pozzolanic properties. Also the carbon content present in the ash also decreases with an increase
in the ash content i.e. some of the carbon content was converted into ash content which enables the ash to
increase with a decrease in the carbon content. At 600-700 ℃, the ash content of the rice husk decreases from
5.999-5.131. The reduction in the ash content with an increase in temperature can be attributed to the effect of
shrinking of the ash present in the furnace and also the transformation from amorphous to crystalline silica.
Also, an increase in porosity of the carbonized rice husk resulted on the increase in temperature at constant time
interval.
0
0.5
1
1.5
2
2.5
540 580 620 660 700 740 780
Unblechedoil
Untreated RHA
0.5M HCl
1M HCl
1.5M HCl
2M HCl
2.5M HCl
ABSORBANCE
7. Development And Characterization Of Adsorbent From Rice Husk Ash To Bleach Vegetable Oils.
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Table 4 represents the effect of carbonization time at constant temperature of 600 ℃, on the analytics of
carbonizing rice husk ash. It is observed that the optimum burning temperature of the carbonized rice husk was
given to be 600 ℃, because it yields the best ash content, carbon content and its porosity during the analysis at
different time interval ranging from 1-3 hrs. The best optimum time was also observed to be 3 hrs based on the
ash content, carbon content and porosity. At 1 hr, the carbon content was higher than that of 2 hrs and that of 2
hrs was higher than that of 3hrs. It simple means that at 3 hrs, the carbon content present in the ash at 1hr and 2
hrs were converted into ash which enables the ash content to increase from 5.88-5.99 g. The result also point out
that high amorphous silica was produced (Nair et al., 2006).
Table 5 represents the characterization of the developed Adsorbent using HCl as Activating Agent. It is
observed that at constant temperature of 600 ℃ and constant time of 3hrs, 1.5M HCl of the pre-treated sample
exhibit the highest ash content compared to the various pre-treated concentrations and yield a porosity of 0.937.
The carbon content of the sample decreases with an increase in the ash content due to the temperature and
burning time effect. 2.5M concentration also exhibit higher properties after the concentration of 1.5M. 0.5M
exhibit the lowest properties compared to the other concentrations of the pre-treated samples.
Results obtained on the effect of varying concentration of HCl acid pre-treated RHA for bleaching of
vegetable oil are presented graphically.
Figure1 represents the effect of varying concentration of HCl acid pre-treated RHA for bleaching of
groundnut oil. It is observed that there is a large difference between the bleached oil and the unbleached oil. An
increase in absorbance leads to a decrease in the wavelength of the oil. The increase in absorbance resulted into
an increase in concentration. This is due to the pigment and chromophones present in the oil. The optimum
bleaching concentration that yields the best bleaching potential among the bleaching agent from 0.5M-2.5M is
observed to be 2M. 2M bleached the oil effective than the other concentration of the acid with a decrease in
absorbance. Absorbance is the different between bleached oil and unbleached oil.
Figure 2 represents the effect of varying concentration of HCl acid pre-treated RHA for the bleaching of
palm kernel oil. It is observed that the absorbance increases with a decrease in the wavelength. Also, the
absorbance increase with increase in the concentration of an acid due to pigment and chromophones. The
absorption is not proportional to the wavelength therefore; increase in wavelength does not increase the rate of
absorption. The optimum bleaching concentration that yields the best bleaching potential among the bleaching
agent is observed to be 2.5M. 2.5M of the sample bleached the oil faster than the other concentration of the acid
at a constant temperature and time interval.
Figure 3 represents the varying concentration of HCl acid pre-treated RHA for the bleaching of palm
oil. It is observed that the wavelength increases from 540-800 nm and the rate of absorbance decreases 2.3-1.4
for all acid concentration. The reduction in absorbance with increase in wavelength can be attributed to the
concentration of the acid due to pigment and chromophones (due to the electrons in the chemical bonds only
absorb certain wavelength of light). At 620 nm, the rate of absorbance is observed to be 1.5 that is to say the
absorbance of 620 nm, is greater than that of 580 nm. It was observed from the graph that untreated sample
exhibit the highest absorbance as the wavelength increases. In general, 2.5M HCl pre-treated sample exhibit the
optimum bleaching potential at constant temperature and time interval compared to the other concentrations
from 0.5-2M HCl samples.
The mean bulk density of the untreated RHA was determined to be 2088.9 kg/𝑚3
which confirm the
literature review value ranging from 2000-2300 kg/𝑚3
(Velupillai et al., 1997).
V. Conclusion
The research aimed at the development and characterization of adsorbent from rice husk ash to bleach
vegetable oils was successfully carried out. The following conclusion can be drawn out from the research work.
The preparation of the rice husk ash by acid leaching of the rice husk (using 0.5M to 2.5M HCl with
mixing ratio of 1 gram to 10 ml of rice husk) followed by calcinations at 600 ℃, the best acid
concentration for the bleaching of the oil was found to be 2M for groundnut oil and 2.5M for both palm
oil and palm kernel oil.
Acid treatment improved the bleaching power of the rice husk ash.
The bulk density of the RHA was found to be 2088.9 kg/𝑚3
The best temperature for calcinations of the rice husk was given as 600 ℃ for 3 hours to produce the
ash in an amorphous phase and not crystalline phase based on literature and ash content.
It was also noted that an increase in the absorbance lead to a decrease in the wavelength in nm and the
unbleached rice husk ash exhibit the best amount of absorbance followed by untreated rice husk ash.
The results presented graphically indicate that the untreated and pre-treated samples (from 0.5M-2.5M
HCl) falls close to each other and the gap between them is slightly small and also below the untreated
oils.
8. Development And Characterization Of Adsorbent From Rice Husk Ash To Bleach Vegetable Oils.
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Acknowledgments
Praise be to Allah (SWT) for his mercy and grace bestowed upon me in seeing this research to completion.
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